Dc offset calibration apparatus and method for differential signals

ABSTRACT

A DC offset calibration apparatus includes a first adjustment unit, a first offset calibration circuit, a second adjustment unit, and a second offset calibration circuit. The first adjustment unit adjusts a first input signal to generate a first output signal according to a first offset calibration signal. The first offset calibration circuit is coupled to the first output signal and the first adjustment unit for determining the first offset calibration signal according to the first output signal and predetermined threshold value. The second adjustment unit adjusts a second input signal to generate a second output signal according to a second offset calibration signal. The second offset calibration circuit is coupled to the second output signal and the second adjustment unit for determining the second offset calibration signal according to the second output signal and the predetermined threshold value. The first and the second input signals are a differential signal pair.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to DC offset calibration technology, and more particularly, to a calibration apparatus and related method, which calibrates DC level of a signal through comparing said signal value and a predetermined threshold value.

2. Description of the Prior Art

Generally speaking, in order to adjust DC offsets resulted from channel effects, manufacturing process variations, power supply voltage variations, temperature variations, or other reasons so that the varying range of the received signals falls within a dynamic range of later-stage circuitry (such as an analog-to-digital converter) and signal distortion due to saturation can be avoided, a DC offset calibration mechanism is designed into receiving ends of communication systems or other systems having this need.

DC offset calibration apparatuses can be divided into two categories, which are on-line calibration and off-line calibration. The on-line DC offset calibration mechanism usually directly utilizes AC coupling to on-the-fly eliminate the DC offset of input signals or utilizes loop controls to eliminate the DC offset of the input signals by way of feedback. However, this mechanism will result in a slow response speed towards change in DC level of the input signals, mainly due to large time constant of resistor and capacitor components. On the other hand, the off-line DC offset calibration mechanism determines an adjustment amount for eliminating the DC offset in advance when the system is off-line, and utilizes the adjustment amount to eliminate the DC offset of the input signals when the system is on-line. However, just because the adjustment is determined off-line, it can hardly timely reflect the real-time change of the DC level of the input signals, so as to dynamically change the adjustment amount. Moreover, in practice the above-mentioned two mechanisms need to detect the DC offset of the input signals across a relatively long time period, in order to obtain a statistical average adjustment amount of the DC offset; hence, the DC offset calibration speed will become even slower. If convergence of a closed loop is further involved, the time required for detecting the DC offset of the input signals will become even lengthened.

SUMMARY OF THE INVENTION

It is therefore one of the objectives of the present invention to provide a DC offset calibration apparatus applied to differential amplifier circuits, which can utilize a symmetrical characteristic of the peak amplitude to calibrate the DC offset of the differential signal pair when two input ends of the differential signal pair are signals having the maximum symmetrical amplitude.

According to an embodiment of the present invention, a DC offset calibration apparatus is disclosed. The DC offset calibration apparatus includes a first adjustment unit, a first offset calibration circuit, a second adjustment unit, and a second offset calibration circuit. The first adjustment unit is used for receiving a first input signal and a first offset calibration signal and for adjusting the first input signal to generate a first output signal according to the first offset calibration signal. The first offset calibration circuit is coupled to the first output signal and the first adjustment unit for determining the first offset calibration signal according to the first output signal and at least one predetermined threshold value. The second adjustment unit is used for receiving a second input signal and a second offset calibration signal and for adjusting the second input signal to generate a second output signal according to the second offset calibration signal. The second offset calibration circuit is coupled to the second output signal and to the second adjustment unit for determining the second offset calibration signal according to the second output signal and the predetermined threshold value. The first input signal and the second input signal are a differential signal pair.

According to an embodiment of the present invention, a DC offset calibration method is disclosed. The DC offset calibration method includes: receiving a first input signal and a first offset calibration signal and adjusting the first input signal to generate a first output signal according to the first offset calibration signal; determining the first offset calibration signal according to the first output signal and at least one predetermined threshold value; receiving a second input signal and a second offset calibration signal and adjusting the second input signal to generate a second output signal according to the second offset calibration signal; and determining the second offset calibration signal according to the second output signal and the predetermined threshold value. The first input signal and the second input signal are a differential signal pair.

According to another embodiment of the present invention, a DC offset calibration method is disclosed. The DC offset calibration method includes receiving a differential signal pair having a first input signal and a second input signal, adjusting a voltage level of the first input signal to generate a first output signal according to a first offset calibration signal, determining the first offset calibration signal according to a comparison result of the first output signal and a predetermined threshold value, adjusting a voltage level of the second input signal to generate a second output signal according to a second offset calibration signal, determining the second offset calibration signal according to a comparison result of the second output signal and the predetermined threshold value, and utilizing an amplifier circuit to deal with an output differential signal pair composed of the first output signal and the second output signal.

These and other objectives of the present invention will no doubt become obvious to those of ordinary skill in the art after reading the following detailed description of the preferred embodiment that is illustrated in the various figures and drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagram of a DC offset calibration apparatus according to a first embodiment of the present invention.

FIG. 2 is a diagram of an embodiment of the differential amplifier circuit shown in FIG. 1.

FIG. 3 is a waveform diagram of an example of the input signal and the output signal in FIG. 1.

FIG. 4 is a diagram of a DC offset calibration apparatus according to a second embodiment of the present invention.

FIG. 5 is a diagram of a DC offset calibration apparatus according to a third embodiment of the present invention.

FIG. 6 is a diagram of a DC offset calibration apparatus according to a fourth embodiment of the present invention.

FIG. 7 is a diagram of a DC offset calibration apparatus according to a fifth embodiment of the present invention.

FIG. 8 is a diagram of a DC offset calibration apparatus according to a sixth embodiment of the present invention.

FIG. 9 is a diagram of a DC offset calibration apparatus according to a seventh embodiment of the present invention.

FIG. 10 is a diagram of a DC offset calibration apparatus according to an eighth embodiment of the present invention.

DETAILED DESCRIPTION

For a differential signal pair, if it is provided with a characteristic of symmetrical peak amplitude or constant envelope (such as the preamble data of the OFDM signal in WLAN systems), then the goal of simultaneously calibrating the DC offset of the positive and negative ends of the differential signal can be achieved simply by simultaneously controlling the DC voltage levels of both the positive and the negative ends of the differential input signals are controlled to converge and become identical when designing the DC offset calibration mechanism. One example for illustrating the differential signal provided with the abovementioned characteristic of symmetrical peak amplitude or constant envelope is shown as the differential signal pair (S₁ and S₂) in FIG. 3, wherein S₁ and S₂ respectively represent the positive signal and the negative signal of the differential signal pair. As shown in FIG. 3, the peak amplitude of the positive signal S₁ (that is, a voltage difference between the peak value to the DC voltage level) is symmetrical to the peak amplitude of the negative signal S₂ (i.e., having the same magnitude but opposite in direction). Thus, as long as the DC voltage levels of the positive signal after calibration (such as S₁′ in FIG. 3) and the negative signal after calibration (such as S₂′ in FIG. 3) are adjusted and converged to an identical value (such as V_(dc) in FIG. 3) when performing the DC offset calibration, it is then assured that when the DC offset calibration of one of the positive and negative signals satisfies the input range requirement of later-stage circuitry, the DC offset calibration of the other will satisfy, too.

Please refer to FIG. 1. FIG. 1 is a diagram of a DC offset calibration apparatus 100 according to a first embodiment of the present invention. As shown in FIG. 1, the DC offset calibration apparatus 100 respectively calibrates input signals S₁ and S₂ (here assuming that the input signals S₁ and S₂ possess the characteristic of symmetrical peak amplitude or constant envelope), and DC offsets of a differential amplifier circuit 105 of the DC offset calibration apparatus 100 caused by manufacturing process mismatch, to generate output signals S₁ and S₂′. The DC offset calibration apparatus 100 further includes adjustment units 110 and 115 (respectively implemented by using subtractors 135 and 140) and offset calibration circuits 125 and 130. The adjustment unit 110 adjusts a voltage level of the input signal S₁ according to a voltage level of a offset calibration signal S₁, and then its adjusted output signal is amplified to generate the output signal S₁′. The adjustment unit 115 adjusts a voltage level of the input signal S₂ according to a voltage level of a offset calibration signal S_(c2), and then its adjusted output signal is amplified to generate the output signal S₂′.

Besides, the offset calibration circuit 125 further includes a capacitor C₁ and a calibration circuit 145 having a transistor Q₁ and a comparator COMP₁, wherein the offset calibration circuit 125 is used for determining the voltage level of the offset calibration signal S_(c1) according to the voltage level of the output signal S₁′ and a predetermined threshold value V_(th). If the output signal S₁′ satisfies a first predetermined condition corresponding to the predetermined threshold value V_(th), the offset calibration circuit 125 will use the comparator COMP₁ to control the turning on of the transistor Q₁, and the capacitor C₁ is then charged to adjust the offset calibration signal S₁. At this time, a closed loop DC offset calibration mechanism is formed in the DC offset calibration apparatus 100 due to the transistor Q₁ being turned on. If the output signal S₁′ does not satisfy the first predetermined condition, the offset calibration circuit 125 will use the comparator COMP₁ to control the turning off of the transistor Q₁, and the offset calibration signal S_(c1) is maintained by the offset calibration circuit 125. At this time, an open loop DC offset calibration mechanism is formed in the DC offset calibration apparatus 100. In addition, the offset calibration circuit 130 further includes a capacitor C₂ and a calibration circuit 150 having a transistor Q₂ and a comparator COMP₂, wherein the offset calibration circuit 130 is used for determining the voltage level of the offset calibration signal S_(c2) according to the voltage level of the output signal S₂′ and the predetermined threshold value V_(th). If the output signal S₂′ satisfies a second predetermined condition corresponding to the predetermined threshold value V_(th), the offset calibration circuit 130 will use the comparator COMP₂ to control the turning on of the transistor Q₂, and the capacitor C₂ is then charged to adjust the offset calibration signal S_(c2). On the other hand, the offset calibration circuit 130 will maintain the offset calibration signal S_(c2) if the output signal S₂′ does not satisfy the second predetermined condition.

As abovementioned, the predetermined threshold value V_(th) is a predetermined threshold voltage level, the first predetermined condition is that the voltage level of the output signal S₁′ exceeds the predetermined threshold voltage level V_(th), and the second predetermined condition is that the voltage level of the output signal S₂′ exceeds the predetermined threshold voltage level V_(th). Hence, if the first predetermined condition is satisfied, the comparator COMP₁ will output a control signal of low logic level for turning on the transistor Q₁. A power source V_(cc) will charge the capacitor C₁ through the transistor Q₁, thus the voltage level of the offset calibration signal S_(c1) will be raised by the charging of the capacitor C₁. The voltage level of the input signal S₁ will be lowered to generate the output signal S₁′ through the subtractor 135. For this reason, a maximum value of the voltage level of the output signal S₁′ is confined by the predetermined threshold voltage value V_(th). Similarly, if the second condition is satisfied, the operation of the offset calibration circuit 130 is the same as the operation of the offset calibration circuit 125. The comparator COMP₂ will output a control signal of low logic level for turning on the transistor Q₂. The power source V_(cc) will charge the capacitor C₂ through the transistor Q₂, thus the voltage level of the offset calibration signal S_(c2) will be raised by the charging of the capacitor C₂. The voltage level of the input signal S₂ will be lowered to generate the output signal S₂′ through the subtractor 140. For this reason, a maximum value of the voltage level of the output signal S₂′ is confined by the predetermined threshold voltage value V_(th). Due to the input signals S₁ and S₂ having a characteristic of symmetrical peak amplitude or constant envelope, the DC offsets of both the input signal S₁ and S₂ tend to become the same value through a specific control mechanism. Therefore, an objective for simultaneously completing DC offset calibrations of the signals S₁ and S₂ can be reached. Therefore for later-stage circuitry (such as an analog-to-digital converter, not shown in FIG. 1), if the value of the predetermined threshold voltage value V_(th) is designed to be smaller than the dynamic range of its input ends, a signal saturation phenomenon will not be observed in the DC offset of the input ends.

Please refer to FIG. 2. FIG. 2 is a diagram of an embodiment of the differential amplifier circuit 105 shown in FIG. 1. FIG. 2 shows a typical differential amplifier circuit, which is composed of a plurality of active elements, such as transistors, to respectively constitute its gain stage and its loading. The implementation and operating principle of such a differential amplifier are well known by those skilled in the art and are therefore not described herein in further detail. Please note that, the differential amplifier circuit 105 further includes a common-mode feedback path coupled between the output end and the input end, for constraining a common-mode voltage (that is, the DC voltage level) of the positive and the negative signals of the output ends to a reference common-mode voltage V_(cm). In this embodiment, the common-mode feedback path is composed of two resistors and one comparator 205 that are coupled to the output ends, wherein the comparator 205 controls two active loadings according to a midpoint voltage of the two resistors and the reference common-mode voltage V_(cm). Through the common-mode feedback mechanism described above, the DC level of the two output signals S₁′ and S₂′ converge and tend to become identical. In addition, due to the differential signal to be processed having a characteristic of symmetrical peak amplitude or constant envelope, when one of the output signals S₁′ and S₂′ is DC offset calibrated by the offset calibration circuits 125 or 130, calibration of the other output signal to the same degree will be warranted. The result for the abovementioned DC offset calibration is referred to in FIG. 3, wherein the waveform shown in the upper half illustrates the input signals S₁ and S₂ before calibration, which respectively have different DC voltage levels V_(dc1) and V_(dc2), and the waveform shown in the lower half illustrates the output signals S₁′ and S₂′ after calibration, which have the same DC voltage levels V_(dc). At this time, if one of the output signals S₁′ and S₂′ (such as the output signal S₁′) is calibrated by the offset calibration circuit 125 to have a peak value smaller than the predetermined threshold value V_(th), the other output signal (such as the output signal S₂′) will be similarly calibrated to have a peak value smaller than the predetermined threshold value V_(th) through the operation of the common-mode feedback path in conjunction with the characteristic of maximum symmetrical amplitude or constant envelope.

Furthermore, by confining the minimum amplitude of two differential output signals (that is, the peak value in the other direction) to the same predetermined threshold voltage level, the objective of calibrating to the same DC offset level can also be achieved. Please refer to FIG. 4. FIG. 4 is a diagram of a DC offset calibration apparatus 400 according to a second embodiment of the present invention. The major difference between the DC offset calibration apparatuses 100 and 400 is that, instead of utilizing the power resource V_(cc) to perform charging in calibrating the differential output signals S₁′ and S₂′ to the same DC offset levels, the DC offset calibration apparatus 400, according to a predetermined threshold voltage level V_(th)′, utilizes respectively the comparators COMP₁, COMP₂ and the capacitors C₁, C₂ of the offset calibration circuits 425 and 430 to perform discharging through transistors Q₁′ and Q₂′ to ground. If a first predetermined condition is satisfied; that is, the voltage level of the output signal S₁′ is smaller than the predetermined threshold voltage level V_(th)′, the comparator COMP₁ will output a control signal of high logic level to turn on the transistor Q₁′. The capacitor C₁ will then be discharged to ground through the transistor Q₁′, thus the voltage level of the offset calibration signal S_(c1) will be lowered by the discharging of the capacitor C₁. Consequently, the voltage level of the input signal S₁ will be raised to generate the output signal S₁′. For this reason, a lowest voltage level of the output signal S₁′ will be confined by the predetermined threshold voltage value V_(th)′. Similarly, if a second condition is satisfied; that is, the voltage level of the output signal S₂′ is smaller than the predetermined threshold voltage level V_(th)′. The capacitor C₂ will then be discharged to ground through the transistor Q₂′, thus the voltage level of the offset calibration signal S_(c2) will be lowered by the discharging of the capacitor C₂. Consequently, the voltage level of the input signal S₂ will be raised to generate the output signal S₂′. For this reason, a lowest voltage level of the output signal S₂′ will be confined by the predetermined threshold voltage value V_(th)′. As abovementioned, the lowest voltage levels of the output signals S₁′ and S₂′ are confined by the same predetermined threshold voltage value V_(th)′. Similarly, the DC offset calibration apparatus 400 of this embodiment will co-operate with the differential amplifier circuit 105 having the common-mode feedback path in FIG. 2, to ensure that both the positive signal and the negative signal are calibrated appropriately. Hence, at later-stage circuitry (not shown in FIG. 4) a signal saturation phenomenon due to DC offset will not be observed even when the signals are amplified.

Please refer to FIG. 5. FIG. 5 is a diagram of a DC offset calibration apparatus 500 according to a third embodiment of the present invention. The DC offset calibration apparatus 500 utilizes respectively the voltage levels of the output signals S₁′ and S₂′, the offset calibration signals S_(c1) and S_(c2), and a predetermined threshold value V_(D), to which the diode units (for easy illustration, two diodes D₁ and D₂ are used for representing the diode units) of the calibration circuits 545 and 550 correspond, for determining the voltage levels of the offset calibration signals S_(c1) and S_(c2), wherein the predetermined threshold value V_(D) is a predetermined threshold voltage difference in this embodiment. When the output signal S₁′ satisfies a first predetermined condition corresponding to the predetermined threshold voltage difference V_(D) (in this embodiment, the first predetermined condition is that a voltage difference between the output signal S₁′ and the offset calibration signal S_(c1) reaches the predetermined threshold voltage difference V_(D)), the offset calibration circuit 525 adjusts the offset calibration signal S₁; otherwise, the offset calibration circuit 525 maintains the offset calibration signal S₁. Similarly, when the output signal S₂′ satisfies a second predetermined condition of the predetermined threshold voltage difference V_(D) (in this embodiment, the second predetermined condition is that a voltage difference between the output signal S₂′ and the offset calibration signal S_(c2) reaches the predetermined threshold voltage difference V_(D)), the offset calibration circuit 530 adjusts the offset calibration signal S_(c2); otherwise, the offset calibration circuit 530 maintains the offset calibration signal S_(c2).

The predetermined voltage difference V_(D) represents a minimum bias voltage for the diodes D₁ and D₂ to be forward conducted, which is actually the turn-on voltage (here assuming that their bias voltages are identical). In other words, when the voltage level of the output signal S₁′ is greater than the voltage level of the offset calibration signal S_(c1) and reaches the predetermined threshold voltage difference V_(D), the diode D₁ will become conducted and the output signal S₁′ will start charging the capacitor C₁ through the diode D₁ and raise the voltage level of the offset calibration signal S₁. Similarly, when the voltage level of the output signal S₂′ is greater than the voltage level of the offset calibration signal S_(c2) and reaches the predetermined threshold voltage difference V_(D), the diode D₂ will become conducted and the output signal S₂′ will start charging the capacitor C₂ through the conducted diode D₂ and raise the voltage level of the offset calibration signal S_(c2). Likewise, the DC offset calibration apparatus 500 of this embodiment will co-operate with the differential amplifier circuit 105 having the common-mode feedback path in FIG. 2 to ensure that both the positive signal and the negative signal are calibrated appropriately. Hence, an erroneous operation will not be observed at later-stage circuitry.

Please refer to FIG. 6. FIG. 6 is a diagram of a DC offset calibration apparatus 600 according to a fourth embodiment of the present invention. In this embodiment, the connection configuration of the diodes D₁ and D₂ in FIG. 5 is replaced by the connection configuration of the diodes D₁ and D₂ in FIG. 6; that is, the P-type regions of the diodes D₁ and D₂ are now coupled to the offset calibration signals S_(c1) and S_(c2), respectively, and the N-type regions of the diodes D₁ and D₂ are now coupled to the output signals S₁′ and S₂′, respectively. Hence, when the voltage level of the output signal S₁′ is lower than the voltage level of the offset calibration signal S_(c1) and reaches the predetermined threshold voltage difference V_(D), the diode D₁ will become conducted and the capacitor C₁ will be discharged through the diode D₁ to lower the voltage level of the offset calibration signal S_(c1). When the voltage level of the output signal S₂′ is lower than the voltage level of the offset calibration signal S_(c2) and reaches the predetermined threshold voltage difference V_(D), the diode D₂ will become conducted and the capacitor C₂ will be discharged through the conducted diode D₂ to lower the voltage level of the offset calibration signal S_(c2). Similarly, the DC offset calibration apparatus 600 of this embodiment will co-operate with the differential amplifier circuit 105 having the common-mode feedback path in FIG. 2 to ensure that both the positive signal and the negative signal are calibrated appropriately. Hence, the output signals S₁′ and S₂′ can be restricted to the same DC offset level, so that erroneous operation will not be observed at later-stage circuitry.

Moreover, if the advantage of the voltage gain provided by the differential amplifier circuit 105 is not necessarily desired, the outputs of the adjustment units 110 and 115 can also be directly fed into the comparators COMP and COMP′ or the diodes D and D′, and then appropriate predetermined threshold voltage levels V_(th), V_(th)′ or appropriate predetermined threshold voltage differences V_(d) or V_(d)′ can be set to reach the goal of calibrating the DC offsets of the input signals S₁ and S₂. Please refer to FIG. 7-FIG. 10. After those skilled in the art understand the embodiments in the above-mentioned FIG. 1, FIG. 4, FIG. 5, and FIG. 6 and what is illustrated in FIG. 7-FIG. 10, the embodiments in FIG. 7-FIG. 10 can be reduced to practice without undue efforts. Hence, detail description and operational principle are not described herein. Likewise, the DC offset calibration apparatuses in FIG. 7-FIG. 10 will co-operate with the differential amplifier circuit 105 having the common-mode feedback path in FIG. 2 to ensure that both the positive signal and the negative signal are calibrated appropriately. But the differential amplifier circuit 105 here is preferably located in the later-stage circuitry of the DC offset calibration mechanism that is shown in FIG. 7-FIG. 10.

In summary, the abovementioned DC offset calibration device performs the DC offset calibration through the closed loop control only when the voltage levels of the output signals S₁′ and S₂′ (which can be the signal voltage level before or after the processing of a differential amplifier) satisfy predetermined condition as abovementioned. However, even when the predetermined condition is not satisfied, the voltage levels of the offset calibration signals during the closed loop control will be maintained by the capacitors C₁ and C₂ having the characteristic of charges buffering. Hence, although at this time the DC offset calibrations are not performed through closed loop control, the DC offset calibrations can still be performed through open loop control. The DC offset calibration apparatus disclosed in the present invention can simultaneously be provided with the advantages of fast speed during the open loop control and undistorted signals during the closed loop control. The present invention is not limited to any specific application, but it is especially suitable for the DC offset of input signals of analog-to-digital converters. At this time, the predetermined threshold value can be designed to be a smaller value than the absolute value of the upper limit or the lower limit of the input dynamic range of the analog-to-digital converter, to make sure that the input signal will fall within the input dynamic range.

Finally it is to be noted that, the abovementioned embodiments of the present invention highlight that the present invention is especially suitable for the differential signal pair having the symmetrical peak amplitude and constant envelope, but the practical applications of the present invention are not limited thereto. Even if the differential signals to be processed do not exactly have the abovementioned specific characteristic, the DC offset calibration apparatuses described in each embodiments of the present invention can bring its calibration effect into full play and still be provided with the advantages of fast speed during the open loop control and undistorted signals during the closed loop control.

Those skilled in the art will readily observe that numerous modifications and alterations of the device and method may be made while retaining the teachings of the invention. 

1. A DC offset calibration apparatus comprising: a first adjustment unit, for receiving a first input signal and a first offset calibration signal and for adjusting the first input signal to generate a first output signal according to the first offset calibration signal; a first offset calibration circuit, coupled to the first output signal and the first adjustment unit, for determining the first offset calibration signal according to the first output signal and at least one predetermined threshold value; a second adjustment unit, for receiving a second input signal and a second offset calibration signal and for adjusting the second input signal to generate a second output signal according to the second offset calibration signal; and a second offset calibration circuit, coupled to the second output signal and the second adjustment unit, for determining the second offset calibration signal according to the second output signal and the predetermined threshold value; wherein the first input signal and the second input signal are a differential signal pair.
 2. The DC offset calibration apparatus of claim 1, wherein: the first offset calibration circuit adjusts the first offset calibration signal when the first output signal satisfies a first predetermined condition corresponding to the predetermined threshold value; and the first offset calibration circuit maintains the first offset calibration signal when the first output signal does not satisfy the first predetermined condition.
 3. The DC offset calibration apparatus of claim 2, wherein: the second offset calibration circuit adjusts the second offset calibration signal when the second output signal satisfies a second predetermined condition corresponding to the predetermined threshold value; and the second offset calibration circuit maintains the second offset calibration signal when the second output signal does not satisfy the second predetermined condition.
 4. The DC offset calibration apparatus of claim 3, wherein: the first offset calibration circuit comprises: a first capacitor, for determining a voltage level of the first offset calibration signal; and a first calibration circuit, coupled to the first output signal and the first capacitor, for controlling the first capacitor to perform charging or discharging to adjust the voltage level of the first offset calibration signal; and the second offset calibration circuit comprises: a second capacitor, for determining a voltage level of the second offset calibration signal; and a second calibration circuit, coupled to the second output signal and the second capacitor, for controlling the second capacitor to perform charging or discharging to adjust the voltage level of the second offset calibration signal.
 5. The DC offset calibration apparatus of claim 4, wherein: the predetermined threshold value is a predetermined threshold voltage level; the first predetermined condition is that a voltage level of the first output signal reaches the predetermined threshold voltage level and enters into a voltage range; and the second predetermined condition is that a voltage level of the second output signal reaches the predetermined threshold voltage level and enters into the voltage range.
 6. The DC offset calibration apparatus of claim 5, wherein: the first calibration circuit comprises: a first comparator, for comparing the first output signal with the predetermined threshold voltage level to generate a first control signal; and a first transistor, having a first end coupled to a reference voltage level, a second end coupled to the first capacitor, and a control end coupled to the first comparator, wherein the control signal controls to turn on the first transistor, and the first capacitor is charged or discharged by the reference voltage level when the voltage level of the first output signal falls within the voltage range; and the second calibration circuit comprises: a second comparator, for comparing the second output signal with the predetermined threshold voltage level to generate a second control signal; and a second transistor, having a first end coupled to the reference voltage level, a second end coupled to the second capacitor, and a control end coupled to the second comparator, wherein the control signal controls to turn on the second transistor, and the second capacitor is charged or discharged by the reference voltage level when the voltage level of the second output signal falls within the voltage range.
 7. The DC offset calibration apparatus of claim 4, wherein: the predetermined threshold value is a predetermined threshold voltage difference; the first predetermined condition is that a voltage difference between the first output signal and the first offset calibration signal reaches the predetermined threshold voltage difference; and the second predetermined condition is that a voltage difference between the second output signal and the second offset calibration signal reaches the predetermined threshold voltage difference.
 8. The DC offset calibration apparatus of claim 7, wherein: the first calibration circuit comprises: a first diode unit, comprising at least one diode, wherein a first connecting end of the first diode unit is coupled to the first output signal and a second connecting end of the first diode unit is coupled to the first capacitor; and the second calibration circuit comprises: a second diode unit comprising at least one diode, wherein a first connecting end of the second diode unit is coupled to the second output signal and a second connecting end of the second diode unit is coupled to the second capacitor.
 9. The DC offset calibration apparatus of claim 1, wherein the first adjustment unit is used for adjusting the voltage level of the first input signal according to the voltage level of the first offset calibration signal and the second adjustment unit is used for adjusting the voltage level of the second input signal according to the voltage level of the second offset calibration signal, and the DC offset calibration apparatus further comprises: a differential amplifier circuit, coupled to the first adjustment unit and the second adjustment unit, for respectively receiving the output of the first adjustment unit and the output of the second adjustment unit to generate the first output signal and the second output signal.
 10. A DC offset calibration method comprising: receiving a first input signal and a first offset calibration signal and adjusting the first input signal to generate a first output signal according to the first offset calibration signal; determining the first offset calibration signal according to the first output signal and at least one predetermined threshold value; receiving a second input signal and a second offset calibration signal and adjusting the second input signal to generate a second output signal according to the second offset calibration signal; and determining the second offset calibration signal according to the second output signal and the predetermined threshold value; wherein the first input signal and the second input signal are a differential signal pair.
 11. The DC offset calibration method of claim 10, wherein the step of determining the first offset calibration signal comprises: adjusting the first offset calibration signal when the first output signal satisfies a first predetermined condition corresponding to the predetermined threshold value; and maintaining the first offset calibration signal when the first output signal does not satisfy the first predetermined condition.
 12. The DC offset calibration method of claim 11, wherein the step of determining the second offset calibration signal comprises: adjusting the second offset calibration signal when the second output signal satisfies a second predetermined condition corresponding to the predetermined threshold value; and maintaining the second offset calibration signal when the second output signal does not satisfy the second predetermined condition.
 13. The DC offset calibration method of claim 12, wherein: the step of adjusting the first offset calibration signal comprises: providing a first capacitor and controlling the first capacitor to perform charging or discharging to adjust a voltage level of the first offset calibration signal; and the step of adjusting the second offset calibration signal comprises: providing a second capacitor and controlling the second capacitor to perform charging or discharging to adjust a voltage level of the second offset calibration signal.
 14. The DC offset calibration method of claim 13, wherein: the predetermined threshold value is a predetermined threshold voltage level; the first predetermined condition is that a voltage level of the first output signal reaches the predetermined threshold voltage level and enters into a voltage range; and the second predetermined condition is that a voltage level of the second output signal reaches the predetermined threshold voltage level and enters into the voltage range.
 15. The DC offset calibration method of claim 13, wherein: the predetermined threshold value is a predetermined threshold voltage difference; the first predetermined condition is that a voltage difference between the first output signal and the first offset calibration signal reaches the predetermined threshold voltage difference; and the second predetermined condition is that a voltage difference between the second output signal and the second offset calibration signal reaches the predetermined threshold voltage difference.
 16. The DC offset calibration method of claim 10, wherein: the step of adjusting the first input signal to generate the first output signal according to the first offset calibration signal comprises: adjusting a voltage level of the first input signal to generate an adjusted first input signal according to a voltage level of the first offset calibration signal; and the step of adjusting the second input signal to generate the second output signal according to the second offset calibration signal comprises: adjusting a voltage level of the second input signal to generate an adjusted second input signal according to a voltage level of the second offset calibration signal; and the DC offset calibration method further comprises: amplifying the adjusted first input signal and the adjusted second input signal to respectively generate the first output signal and the second output signal.
 17. A DC offset calibration method comprising: receiving a differential signal pair having a first input signal and a second input signal; adjusting a voltage level of the first input signal to generate a first output signal according to a first offset calibration signal; determining the first offset calibration signal according to a comparison result of the first output signal and a predetermined threshold value; adjusting a voltage level of the second input signal to generate a second output signal according to a second offset calibration signal; determining the second offset calibration signal according to a comparison result of the second output signal and the predetermined threshold value; and utilizing an amplifier circuit to deal with an output differential signal pair composed of the first output signal and the second output signal.
 18. The DC offset calibration method of claim 17, wherein the amplifier circuit comprises a common-mode feedback path.
 19. The DC offset calibration method of claim 17, wherein: when the comparison result of the first output signal and the predetermined threshold value is a first state, a closed loop is formed to adjust the voltage level of the first input signal; and when the comparison result of the first output signal and the predetermined threshold value is a second state, an open loop is formed to adjust the voltage level of the first input signal.
 20. The DC offset calibration method of claim 17, wherein the predetermined threshold value is one input of two input ends of a comparator.
 21. The DC offset calibration method of claim 20, wherein an output end of the comparator is coupled to a gate of a transistor.
 22. The DC offset calibration method of claim 17, wherein the predetermined value is determined by turn-on voltages of at least one diode. 